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Revision as of 11:33, 16 September 2015

Intracellular signal transduction

HYPOTHESIS 6: Expression of OmpR-Regulated-RFP leads to OmpR dependent production of red fluorescence protein (RFP)

Binding of the low concentration protein biomarker to the affibody molecules of the receptor will lead to conformational changes in the downstream region (EnvZ region) of the receptor. This in turn activates OmpR intracellularly. Our first goal was to express RFP which is OmpR regulated. There was already a BioBrick (BBa_M30011) in the iGEM distribution kit that we used to fulfil our goal. As EnvZ deficient strain (BW25113 strain) does not contain EnvZ, it will not have any intracellular interference of endogenous OmpR activation with that of OmpR-Regulated-RFP. In high osmolarity, EnvZ exhibits its kinase property, leading to enormous amount of phosphorylated OmpR inside the cell which activates transcription of RFP containing gene in OmpR-Regulated-RFP [REFERENCE].

# Experiments for hypothesis 6 Status
1 Can we express RFP in Top10 and BW25113 E. coli bacteria? Positive Go to experiment
2 Is OmpR-Regulated-RFP actually OmpR dependent? Unknown Go to experiment
3 Can we characterize Part A even more? Unknown Go to experiment

Experiment 1: Can we express RFP in Top10 and BW25113 E. coli bacteria?

Method: Top 10 and BW25113 (EnvZ deficient strain) chemo-competent E. coli bacteria were transformed with BBa_M30011 (See Transformation Protocol) after extraction from the iGEM distribution kit.

Result: RFP was successfully expressed in both the strains. Figure A shows red colonies with BBa_M30011 in BW25113 strain.

OmpR regulated RFP production

Figure A. BW25114 E. coli transformed with OmpR-Regulated-RFP (BBa_M30011).

Experiment 2: Is OmpR-Regulated-RFP actually OmpR dependent?

Method: Osmolarity test was performed in triplicates, first in TOP10 E. coli containing BBa_M30011 followed by in the BW25113 E. coli strain. Bacteria were grown in minimal media with four different concentrations of sucrose (0%, 5%, 10% and 15%). RFP was then measured in the fluorescence plate reader (Osmolarity protocol). An osmolarity experiment setup is shown in Figure B.

Osmolarity experiment

Figure B: Preparation of osmolarity experiment with the positive (BBa_J04450) and negative controls (BBa_K1766005) to the right.

Result: Figure C depicts osmolarity dependence of OmpR-Regulated-RFP BioBrick. TOP10 bacteria had increasing order of red fluorescence (in terms of fold change) depending on the increasing osmolarity level whereas BW25113 showed minor change in fluorescence intensity as expected.

Osmolarity experiment

Figure C. Fluorescence of TOP10 and BW25113 transformed with BBa_M30011 and cultured at different osmolarities. Statistical analysis was done by Student’s t-test and standard error bars of fold changes are shown in the bar diagram. Changes in the fluorescence intensities in 5% and 15% were significant in Top 10, and that of 10% and 15% were significant in BW25113. ‘*’ signifies significant P value. ns: P > 0.05 (not significant). *P ≤ 0.05. **P ≤ 0.01. ***P ≤ 0.001. ****P ≤ 0.0001.

These results together show that the BioBrick is OmpR controlled and osmolarity dependent.

Experiment 3: Can we characterize Part A even more?

Method: The same BioBrick (BBa_M30011) was cloned in the low copy plasmid (pSB3C5) in order to have further and detailed characterization of this part. This time some deviations were made in the protocol. Here, TOP10 E. coli bacteria were grown in special osmo media (LB + Sucrose) in four replicates (See Aternative Osmolarity Protocol) instead of minimal media.

Results: The Y axis in Figure D shows average fluorescence/OD instead of fluorescence fold changes. These are compiled data from the Experiment 2 (BBa_M30011 in pSB1C3 in Top 10 strain) and Experiment 3 (BBa_M30011 in pSB3C5 in Top 10 strain). The standard deviation between the samples was much smaller in low copy plasmid. It can be explained by the use of new osmo media as the changes were more consistent than the minimal media where the cells were under more stress. OmpR dependent change in the low copy plasmid is less pronounced than the conventional one (pSB1C3) in this Figure. Possible explanation could be due to the composition stoichiometry in the cell (Ref). The absolute fluorescence was lower in pSB3C5 as expected. However, fluorescence fold change (compared to 0%) remained roughly the same in pSB3C5 and pSB1C3.

Comparison between BBa_M30011 fluorescence in high (pSB1C3) and low (pSB3C5) copy number plasmid

Figure D. Comparison between BBa_M30011 fluorescence in high (pSB1C3) and low (pSB3C5) copy number plasmid.

Conclusion for hypothesis

OmpR-Regulated-RFP was expressed in E. coli and it is characterized comprehensively. It was proven to be osmolarity dependent. The results are more stable and reliable when cultured in LB media and in low copy plasmid.


HYPOTHESIS 7: Expression of MicF-Regulated-GFP leads to constitutive expression of green fluorescence protein (GFP) which can be silenced with MicF RNA

MicF RNA has been shown to regulate post-transcriptional expression of the ompF gene. The micF gene encodes an antisense RNA which binds to its target region in the ompF gene. This leads to inhibition of translation Ref. Taking this fact into consideration, we tried to incorporate the micF target (micF-T) and GFP in one plasmid in order to express micF regulated GFP. [REFERENCE].

# Experiments for hypothesis 7 Status
1 Can we express the GFP construct 1 in E.coli ? Unknown Go to experiment
2 Can we express the GFP construct 2 in E.coli? Unknown Go to experiment

Experiment 1: Can we express the GFP construct 1 in e.coli ?

Method: Osmolarity tests were performed on TOP10 E. coli transformed with MicF-Regulated-GFP, according to ALTERNATIVE OSMOLARITY PROTOCOL. This was done to characterize the osmolarity dependence of the construct’s GFP production i.e. the micF inhibitory effect. E. coli transformed with BBa_K608011 (1) and BBa_J23106-BBa_I13504 (2) were used as positive controls. BBa_K1766005 was used as a negative control.

Results: Sequencing showed successful cloning of MicF-Regulated-GFP. Osmolarity testing showed that no significant fluorescence was achieved (See figure E).

MicF-Regulated-GFP

Figure E. Relative fluorescence of E. coli transformed with MicF-Regulated-GFP cultured at different osmolarities.

Conclusion: A conclusive result that GFP is not produced made us believe that the design of the construct was faulty. After analyzing the gene we found a reading frame within the micF target gene which ran into two stop codons before reaching the GFP reading frame. We decided to try to make a fusion protein instead with the micF target included in the GFP.

Experiment 1: Can we express the GFP construct 2 in e.coli ?

Method: Figure F shows the illustration of the second MicF-regulated-GFP. To create this construct a site directed mutagenesis was performed on the first MicF-regulated-GFP. Mutagenesis primers was designed and ordered from IDT according to ARTICLE with the scars removed and the restriction site of BsmI introduced so that screening could be performed with restriction analysis. The mutagenesis protocol was made based on the product cheat recommendation on the polymerase used. The selection was enabled by the fact that the cells with the new construct had visible fluorescence.

Plasmid illustration of repaired micF-Regulated-GFP

Results: All picked colonies after transformation with the mutagenesis product showed positive result on the restriction analysis and confirmation was made by sequencing. Fluorescence was visible under UV light.

Conclusion: The only conclusion that was made is that the new construct produces fluorescence. Next step: To test if the MicF-Regulated-GFP construct actually works as intended, with the micF dependent inhibition, an osmolarity test would be conducted. The test would be performed on TOP10 E.coli as well as on the EnvZ deficient strain BW25113. Both strains would be transformed with the MicF-Regulated-GFP fusion protein in a low copy plasmid. It could also be combined on the same plasmid with the micF gene which is ompR regulated.

HYPOTHESIS 8: Expression of OmpR-Regulated-GFP/RFP leads to OmpR dependent regulation of RFP/GFP production

Introduction: This is the final part of the fluorescence signaling system. This part is created in order to investigate both the effects of phosphorylated and dephosphorylated OmpR. The main idea is to introduce micF RNA in a plasmid, together with OmpR-Regulated-RFP and MicF-Regulated-GFP. In high intracellular osmolarity condition, micF binds to micF-T in MicF-Regulated-GFP and silences production of GFP (Red colonies are pronounced here). In contrast, GFP is pronounced in low osmolarity when micF is not binding to micF-T. Thus, it makes the whole system sensitive to both kinase and phosphatase activity in the BAR.

Methods: Osmolarity tests should be performed according to ADAPTED OSMOLARITY PROTOCOL to characterize the construct’s GFP and RFPs osmolality dependence. We want to see if the GFP production is inhibited by the OmpR dependent micF and if the RFP production is induced by phosphorylated OmpR.

Results: MicF was also cloned together with the OmpR dependent promoter in pSB1C3. The part was confirmed by sequencing but not characterized. The rest of the construction on this part was not attempted due to lack of time. Thus, it’s characterization is left for future study.


HYPOTHESIS 9: Expression of OmpR-Regulated-RhII leads to OmpR dependent expression of quorum sensing molecule BHL

Introduction: RhlI is a quorum synthase which produces the quorum sensing molecule N-butyl-homoserine lactone (BHL). In this construct RhlI is under the control of an OmpR dependent promoter. OmpR is activated when it is phosphorylated by the EnvZ receptor. In wild type E. coli this will occur at high osmolarity conditions but not at low osmolarity. To show that the OmpR-Regulated-RhlI BioBrick (BBa_K1766005) works as expected we wanted to prove that it produces BHL in an OmpR dependent manner.

Method: To show that expression of OmpR-Regulated-RhlI is controlled by OmpR we performed an osmolarity bioassay. We used Chromobacterium violaceum in soft agar as a BHL reporter. In the presence of BHL the C. violaceum lab strain CV026 produces a violet pigment called violacein. E. coli transformed with OmpR-Regulated-RhlI was cultured overnight in high and low osmolarity media. The cultures or supernatants were then applied to separate wells on the bioassay plates. E. coli transformed with RhlI generator (BBa_K082035) was used as a positive control. Untransformed E. coli was used as a negative control. [See AHL Osmolarity Dependence Protocol]

Results for supernatant plates: On all plates, weak purple pigmentation could be seen around one well. This well contained supernatant from high osmolarity cultures of OmpR-Regulated-RhlI. No purple pigmentation could be seen around the other wells.

Figure H. Spent bacterial culture supernatant applied to plates containing C. violaceum in soft agar.

Results for bacterial culture plates: Purple pigmentation could be seen around all wells except the negative control. There was visibly less pigmentation around the positive control compared to the OmpR-Regulated-RhlI samples. The diameter of the purple pigmentation around the high and the low osmolarity samples was measured and compared. The high osmolarity samples, on average, had a 23% bigger radius than the low osmolarity samples.

Left: Figure G. Bacterial cultures t applied to plates containing C. violaceum in soft agar. Right: Figure H. Violacein induction in C. violaceum. Comparison between E. coli transformed with OmpR-Regulated-RhlI, cultured at high and low osmolarity.